Performance fabrics and related articles

ABSTRACT

An embodiment of the present disclosure is a performance fabric. The performance fabric includes a plurality of warp yarns extending along a warp direction. The warp yarn includes a first warp yarn and a second warp yarn that is directly adjacent to the first warp yarn. The plurality of warp yarns are blended staple warp yarns each of which has cotton fibers and regenerated cellulosic fibers. The performance fabric includes a plurality of weft yarns interwoven with the plurality of warp yarns to define a woven fabric structure. The plurality of weft yarns includes at least one yarn comprising thermoplastic fibers or a blend yarn comprising regenerated cellulosic fibers.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application claims the benefit under 35 U.S.C. § 119 of Indian Patent Application No. 201621031577, filed Sep. 15, 2016. The contents of which is incorporated by reference into the present application.

TECHNICAL FIELD

The present disclosure relates to performance fabrics, and in particular to a performance fabrics having multiple fiber.

BACKGROUND

Sheeting fabrics require a number of different end-use properties to achieve widespread market acceptance. Sheeting fabrics should be wrinkle resistant and/or have easy care characteristics while having the requisite softness, durability, color retention, and quick dry properties. Typical sheeting fabrics are formed primarily from cotton fibers. Chemical finishes are often applied to cotton sheeting fabrics to attain the desired wrinkle resistance/easy care attributes. Sheeting fabrics that comprise cotton and polyester fibers may have improved wrinkle resistance due in part to the presence of the polyester fibers in the structure. However, manufacturers still seek an adequate balance of the end-use properties at a price the market will accept. Development within such cost constraints in view of end-use requirements is difficult and not a predictable endeavor.

SUMMARY

An embodiment of the present disclosure is a performance fabric. The performance fabric includes a plurality of warp yarns extending along a warp direction. The warp yarn includes a first warp yarn and a second warp yarn that is directly adjacent to the first warp yarn. The plurality of warp yarns are blended staple warp yarns each of which has cotton fibers and regenerated cellulosic fibers. The performance fabric includes a plurality of weft yarns interwoven with the plurality of warp yarns to define a woven fabric structure. The plurality of weft yarns include at least one yarns comprising thermoplastic fibers.

Another embodiment of the present disclosure is a performance fabric. The performance fabric includes a plurality of warp yarns extending along a warp direction. The warp yarns include a first warp yarn and a second warp yarn that is directly adjacent to the first warp yarn. The plurality of warp yarns are blended staple warp yarns each of which has cotton fibers and regenerated cellulosic fibers. The performance fabric includes a plurality of weft yarns interwoven with the plurality of warp yarns to define a woven fabric structure. The plurality of weft yarns includes at least one yarn comprising a blend of cotton fibers and regenerated cellulosic fibers.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing summary, as well as the following detailed description of illustrative embodiments of the present application, will be better understood when read in conjunction with the appended drawings. For the purposes of illustrating the present application, there is shown in the drawings illustrative embodiments of the disclosure. It should be understood, however, that the application is not limited to the precise arrangements and instrumentalities shown.

FIG. 1 is a schematic view of a woven fabric according to an embodiment of the present disclosure;

FIG. 2 is a cross-sectional view of the woven fabric taken along line 2-2 in FIG. 1;

FIG. 3 is a schematic view of a woven fabric according to another embodiment of the present disclosure;

FIG. 4 is a detailed view of the woven fabric in FIG. 3;

FIG. 5 is a cross-sectional view of the woven fabric taken along line 5-5 in FIG. 1;

FIG. 6 is a cross-sectional view of the woven fabric taken along line 6-6 in FIG. 1;

FIG. 7 is a sectional view of a woven fabric according to another embodiment of the present disclosure;

FIG. 8 is another sectional view of the woven fabric shown in FIG. 7;

FIG. 9 is a sectional view of a woven fabric according to another embodiment of the present disclosure;

FIG. 10 is another sectional view of the woven fabric shown in FIG. 9; and

FIG. 11 is a schematic view of a woven fabric according to an embodiment of the present disclosure;

FIG. 12 is a cross-sectional view of the woven fabric taken along line 12-12 in FIG. 11; and

FIG. 13 a process flow diagram for manufacturing the sheeting fabric according to an embodiment of the present disclosure.

DETAILED DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS

Embodiments of the present disclosure also include flat woven fabrics that includes at least three fiber types to achieve desirable end-use properties. In various embodiments of the present disclosure, the woven fabric includes cotton fibers, regenerated cellulosic fibers, and/or various types of thermoplastic fibers, such as thermoplastic staple fibers or thermoplastic filaments. The cotton fibers provide a natural hand-feel and improved comfort. The regenerated cellulosic fibers (e.g. viscose rayon, lyocell, modal, and the line) enhance softness, luster, and brilliance to woven fabric. The thermoplastic fibers add strength, wrinkle resistance, and quick dry properties. The fiber combinations described herein may be implemented in a flat woven fabric or a terry woven fabric using a number of different yarn configurations.

The woven fabrics as described herein are suitable for home textile applications. Accordingly, the fabrics can be formed into one or more different bedding articles, such as a flat sheet, a fitted sheet, a pillow case, a sham, a comforter, a duvet, a bed-skirt, coverlet and/or a blanket. The fabrics can be formed into one or more different bath articles, such as a towels, hand towels, wash clothes, bath matts, bath robes, and the like.

Referring to FIGS. 1 and 2, an embodiment of the present disclosure is a flat woven fabric 10 includes a warp component having warp yarns 20, and a weft component including weft yarns 40 that are interwoven with the warp yarns 20 to define the woven fabric. The weft yarns 40 may be referred to as fill or pick yarns. The warp yarns 20 extends along a warp direction 4 and includes first warp yarn 20 a, a second warp yarn 20 b, a third warp yarn 20 c and a fourth warp yarn 20 d, etc. The weft yarns 40 extend along a weft or fill direction 6 that is perpendicular to the warp direction 4. The weft yarns 40 include a first weft yarn 40 a, a second warp yarn 40 b, a third weft yarn 40 c and a fourth weft yarn 40 d, etc. The woven fabric 10 includes a face 12 and back 14 opposite the face 12 along a thickness direction 8 that is perpendicular to the warp direction 4 and the weft direction 6. The warp yarns 20 are primarily blended spun yarns that include cotton fibers and regenerated cellulosic fibers. The weft yarns 40, however, may have a number of different yarn structures and arrangements, all of which include a form of thermoplastic fibers, such as polyester staple fibers or polyester continuous filaments, as will be described further below.

Continuing with FIGS. 1 and 2, the woven fabric 10 includes weft yarns 40 a-40 b each of which extend along the weft insertion path 19. The weft insertion path 19 is shown in dashed lines in FIG. 1. As used herein, the weft insertion path 19 extends along the weft direction 4 around the warp yarns 20 across an entirety of the width of the woven fabric 10. As illustrated, the weft insertion path extends under (with respect to the sheet) warp 20 a, over warp yarn 20 b, under warp yarn 20 c, and over warp yarn 20 d. A person of skill in the art will appreciated that the weft insertion path 19 varies from one woven design to another woven design.

The woven fabric 10 as described herein may be defined by a number of different woven structures having a woven design repeat 18. As used herein, a woven design repeat 18 includes at least a first warp yarn 20 a, a second warp yarn 20 b, and at least one weft yarn 40. For example, a plain weave fabric has a woven design repeat that includes two adjacent warp yarns 20 a, 20 b and two adjacent weft yarns 40 a, 40 b. Depending on the particular design, woven design repeats may repeat along: a) the weft direction 4; b) the warp direction 6; or both the weft direction 4 and warp directions 6. However, the design of the woven fabric 10 is not limited to a plain weave. For example, the woven fabric can have a number of exemplary woven structures including, but are not limited to: plain weaves; basket weaves, rib weaves (e.g. 2×1 rib weave; 2×2 rib weave; or 3×1 rib weave) twill weaves; oxford weaves; percale weaves, satin weaves (e.g. satin dobby base, satin stripe satin 5/1, satin 4/1 satin; 4/1 satin base strip; 4/1 stain swiss dot; 4/1 down jacquard; 5/1 satins), or sateen weaves. In one example, the woven fabric is a plain weave. In another example, the woven fabric is a basket weave. In another example, the woven fabric is a rib weave. In another example, the woven fabric is a twill. In another example, the woven fabric is an oxford weave. In another example, the woven fabric is a satin weave as shown in FIGS. 3-6. Furthermore, a number of exemplary satin constructions are possible. For instance, in one satin weave example, the woven fabric is a 4/1 satin. In another example, the woven fabric is a 4/1 satin dobby diamond weave. In another example, the woven fabric is a 4/1 satin dobby stripe. In yet another example, the woven fabric is a 4/1 satin jacquard weave. In another example, the woven fabric is a 5/1 satin. In still another example, the woven fabric may be a 6/1 satin. In another example, the woven fabric is a 7/1 satin. In yet another example, the woven fabric is a 8/1 satin. In another example, the woven fabric is a 9/1 satin. In another example, the woven fabric is a 10/1 satin.

Each of the woven fabrics described herein include warp yarns 20 that are blended staple yarns. The warp yarns may therefore be referred to as blended staple yarns formed from staple length fibers arranged in a twisted assembly using typical short staple yarn spinning systems as further described below. The blended staple yarns that include cotton fibers and regenerated cellulosic fibers. Any type of cotton fiber that is suitable for staple yarn manufacture may be used, such a Pima and/or Egyptian cotton fibers. Regenerated cellulosic fibers include rayon fibers in staple form and/or filament form. Rayon is considered a manufactured fiber composed of regenerated cellulose, as well as manufactured fibers composed of regenerated cellulose in which substituents have replaced not more than 15% of the hydrogens of the hydroxyl groups. A lyocell fiber is where the fiber is composed of cellulose precipitated from an organic solution in which no substitution of the hydroxyl groups takes place and no chemical intermediates are formed. Modal is a modified rayon fiber that has high tenacity and high wet modulus. Modal fibers are dimensionally stable and do not shrink or get pulled out of shape when wet like. Modal fibers are also wear resistant and strong while maintaining a soft, silky feel.

The blended warp yarns 20 may have range of cotton and cellulosic fiber content. The blended warp yarns may include between about 20% to about 80% by weight (of the yarn) of the cotton fibers and also between about 20% to about 80% by weight of the cellulosic synthetic fibers. In one example, the blended warp yarns have about 25% to about 45% by weight of the cotton fibers and about 55% to about 75% by weight of the cellulosic synthetic fibers. In yet another example, the blended warp yarns preferably have about 40% by weight of the cotton fibers and 60% by weight of the cellulosic synthetic fibers. In yet another example, the blended warp yarns preferably have about 30% to by weight of the cotton fibers and 70% by weight of the cellulosic synthetic fibers. It should be understood that the amount of cellulosic fiber content specified above include viscose rayon fibers, model fibers, and/or lyocell fiber.

The blended warp yarns 20 may have a range of linear densities that are suitable for bedding applications. For example, the blended warp yarn 20 can have a count between 20 Ne (266 denier) and about 120 Ne (44.3 denier). In one example, the warp yarn count is between 20 Ne (266 denier) and about 100 Ne (53.1 denier). In another example, the warp yarn count is between 20 Ne (266 denier) and about 60 Ne (88.6 denier). In another example, the warp yarn count is between 20 Ne (266 denier) and about 40 Ne (133 denier). In yet another example, the warp yarn count is 20 Ne (266 denier) and about 30 Ne (177 denier).

The blended warp yarns 20 may be single end yarns or plied yarns. For instance, the blended warp yarns may be plied yarn, such as a two ply yarn or a three-ply yarn. For plied yarns, at least one of the ends in the plied yarn is a blended yarn comprising cotton fiber and regenerated cellulosic fibers. However, each one of the yarns in the plied yarn structure is blended yarn that includes cotton fibers and regenerated cellulosic fibers.

The blended warp yarns may be any type of spun staple yarn structure. For example, the blended warp yarns may be ring spun yarns, open end yarns, rotor spun yarns, vortex spun yarns, core spun yarns, jet spun yarns, or compact spun yarns. Preferably, the blended warp yarns are ring spun yarns. The blended warp yarn can, however, be any type of spun yarn structure.

The woven fabrics as described herein may utilize number of different techniques to alter the overall thread count and vary the fiber blend. For instance, the woven fabric 10 as shown in FIGS. 1 and 2 may be forming to include single-end pick insertion. Alternatively, as illustrated in FIGS. 3-8, the woven fabrics of the present disclosure may be formed utilizing co-insertion techniques to insert multiple weft yarns along a weft insertion path 19 in a single weft insertion event during weaving. “Co-insertion” is weaving technique where multiple pick or weft yarns are inserted into the warp shed at one time during weaving. In co-insertion, for example, two pick yarns supplied from two different yarn packages are inserted at one time through the shed during weaving. Co-insertion may also include inserting three or more yarns supplied from the three or more different yarn packages into the shed during weaving. Alternatively, co-insertion may also include inserting two or more yarns supplied from a single yarn package into the shed in a single pick insertion event during weaving. Accordingly, each weft yarn group can have between one weft yarn (see FIGS. 1-2) and four (or more) weft yarns (see FIGS. 3-8) inserted during a single insertion event and that extend along weft insertion path 19. By inserting groups of multiple weft yarns into the shed during a weft insertion event, it is possible to attain increased weft (or pick or fill) densities and therefore higher thread counts. Thus, the woven fabrics as described herein may be constructed to have higher weft yarn densities than what is otherwise possible, and thus higher thread counts, yet the woven fabric exhibits desirable fabric quality, softness, hand, and drape suitable for bedding applications. The thread count of the woven fabrics made in accordance with present disclosure are typically greater than about 200 and can be as high as about 1400 (or even higher). The thread count as used herein is the total number of yarns in square inch of fabric. The thread count is determined by counting the total number of yarn ends along a given length of fabric. In other words, plied yarns are considered one yarn for the purpose of determining thread count.

The warp yarns and weft yarns in the fabrics described herein are arranged to achieve desired warp and weft end densities, respectively, and thus desired thread count, for bedding applications. In accordance with an embodiment of the present disclosure, the woven fabric has a warp end density between about 50 warp ends per inch and about 350 warp ends per inch. In one example, the warp end density is between about 50 and 150 warp ends per inch. In another example, the warp end density is between about 150 and 450 warp ends per inch. In another example, the warp end density is between about 450 and 350 warp ends per inch. Furthermore, the weft yarns are arranged to define a weft end density between about 50 weft yarns per inch and about 700 weft yarns per inch (or more). In one example, the weft yarn density is between about 100 and about 700 weft yarns per inch. In one example, the weft yarn density is between about 100 and about 300 weft yarns per inch. In another example, the weft yarn density is between about 300 and about 500 weft yarns per inch. In another example, the weft yarn density is between about 500 and about 700 weft yarns per inch. The weft yarn density has used herein refers to the total number of separate weft yarns along a length of the woven fabric. For example, a weft yarn density of about 50 picks per inch refers the 50 total weft yarns per inch of woven fabric. If the weft yarn groups are inserted during a single weft insertion event and each weft yarn group includes three (3) weft yarns, then there would be about 16 total weft yarn groups per inch of fabric and 48 picks per inch.

The woven fabrics 10, 210,310, and 510 as described herein have a number of different weft yarn constructions and arrangements to achieve the desired fabric fiber blend. For example, as shown in FIGS. 1 and 2, the weft yarns 40 are single end weft yarns. In one example, the weft yarn may be a continuous filament yarn. In another example, the weft yarns include a combination of a spun staple yarn and a continuous filament yarn. In another example, the weft yarns may be blended spun yarns that include thermoplastic fibers and either cotton fibers or cellulosic synthetic fibers. The variants of possible weft yarns are described next.

Referring to FIGS. 3-6, a woven fabric 110 includes warp yarns 20 and a plurality of weft yarn groups 140 a, 140 b, 140 c, 140 d . . . 140 n. The warp yarns 20 shown in FIGS. 3-6 are the same as the warp yarns described above with respect to the woven fabric 10 and shown in FIGS. 1-3. The woven fabric 110 shown in FIGS. 3-6 includes also a woven design repeat 18 that is similar to the woven design repeat 18 shown in FIGS. 1-2 and described above. Furthermore, the woven design repeat 18 for fabric 110 includes a first warp yarn 20 a and a second warp yarn 20 b. Each warp yarn 20 a-20 d has a first side portion 22 and a second side portion 24. In the embodiment shown in FIGS. 3-6, each weft yarn group 140 a-140 d includes at least one yarn 145 a-145 d, for example a plurality of yarns 145 a-145 d, inserted through a warp shed during a single weft insertion event to further increase the weft count.

As shown in FIGS. 3-6, in each weft yarn group 140 a-140 d, the separate weft yarns 145 a-145 d are substantially parallel with respect to each other and are grouped together as they extend along the weft insertion path 19 through the woven fabric 110. The weft yarns 145 a-145 d are configured as continuous filament yarns. The continuous filament weft yarns in fabric 110 include filament yarns formed from a number of different polymer types. For instance, the filament yarns may include polyethylene terephthalate (PET or polyester) filaments, polylactic acid (PLA) filaments, polypropylene (PP) filaments, and/or polyamide filaments. Preferably, the continuous filament yarns are polyester filament yarns.

The continuous filament weft yarns 145 a-145 d for fabric 110 may have a range of linear densities suitable for bedding applications. For instance, the continuous filament weft yarns have a linear density between 15 denier (354.3 Ne) to about 150 denier (55.4 Ne). In one example, the continuous filament weft has a count between 20 denier to about 150 denier. In one example, the continuous filament weft has a count between 25 denier to about 150 denier. In one example, the continuous filament weft has a count between 30 denier to about 150 denier. In one example, the continuous filament weft has linear density between 40 denier to about 150 denier. In one example, the continuous filament weft has linear density between 50 denier to about 150 denier. In one example, the continuous filament weft has linear density between 75 denier to about 150 denier. In one example, the continuous filament weft has linear density between 80 denier to about 150 denier. In one example, the continuous filament weft has linear density between 100 denier to about 150 denier. Preferably, the continuous filament yarns have a linear density between 50 denier and 100 denier. However, ranges outside of and within the stated ranges are possible.

The continuous filament weft yarns 145 a-145 d in fabric 110 may be single end yarns or plied yarns. For instance, the continuous filament weft yarns may be plied yarn, such as a two ply yarn or a three-ply yarn. For plied yarns, at least one of the ends in the plied yarn is a continuous filament weft yarns comprising synthetic filaments. However, each one of the yarns in the plied yarn structure comprising synthetic filaments.

As shown in FIGS. 3-6, the woven fabric 110 may be formed using pick co-insertion whereby a multiple ends of filament yarns 145 a-145 d are grouped together and extend through the woven fabric along the weft insertion path 19. In one example, the woven fabric 110 may include one continuous filament yarn (as in FIG. 1-3) up to four continuous filament yarn (or more, such as five or even six continuous filament yarns) with each continuous filament yarn having a denier between 15 denier and 150 denier. In one example, the woven fabric 10 may include one continuous filament yarns with each yarn having a denier between 15 denier and 150 denier. In one example, the woven fabric 10 may include groups of two continuous filament yarns with each yarn having a denier between 15 denier and 150 denier. In another example, the woven fabric 10 may include groups of three continuous filament yarns with each yarn having a denier between 15 denier and 150 denier. In another example, the woven fabric 10 may include groups of four continuous filament yarns with each yarn having a denier between 15 denier and 150 denier. In another example, the woven fabric 10 may include groups of five continuous filament yarns with each yarn having a denier between 15 denier and 150 denier. In another example, the woven fabric 10 may include groups of six continuous filament yarns with each yarn having a denier between 15 denier and 150 deniers.

Another embodiment shown in FIGS. 7-8 is another sateen woven fabric 210 is formed from blended warp yarns 20 and a plurality of weft yarns arranged in weft yarn groups 240 a. FIGS. 7-8 are sectional views of the woven fabric 210. It should be appreciated that a plane view of the woven fabric 210 is similar to the view illustrated in FIG. 3. As shown in FIGS. 7-8, each weft yarn group 240 a-240 d includes multiple separate weft yarns 245 a, 245 b, 245 c, 245 d . . . 245 n that are substantially parallel with respect to each other and are grouped together as they extend along the weft insertion path 19 through the woven fabric 210. In the embodiment shown in FIGS. 7-8, each weft yarn groups 240 a-240 d include two different yarns. As illustrated, the weft yarn groups 240 a-240 d may include a first yarn type configured as a spun yarn 245 a and a second yarn type that is a continuous filament yarn 245 b-245 d.

Continuing with FIGS. 7 and 8, the spun yarn 245 a is a staple yarn structure and is referred to as a spun weft yarn 245 a. The spun weft yarn 245 a may be a blended spun yarn that includes cotton fibers and cellulosic synthetic fibers (as described above) or a blended spun yarn comprising cotton fibers and thermoplastic fibers. The thermoplastic fibers are preferably polyester fibers. However, other thermoplastic fibers can be used. Furthermore, the spun weft yarn may comprise exclusively cotton fibers.

The spun weft yarn 245 a may be any type of spun staple yarn structure. For example, the second weft yarn may be ring spun yarns, open end yarns, rotor spun yarns, vortex spun yarns, core spun yarns, jet spun yarns, or compact spun yarns. Preferably, the spun weft yarns 245 a are ring spun yarns. The spun weft yarns 245 a can, however, be any type of spun yarn structure. The spun weft yarn 245 a may have a range of linear densities that are suitable for bedding applications. For example, the spun weft yarn 245 a can have a count between 20 Ne (266 denier) and about 120 Ne (44.3 denier). In one example, the spun weft yarn count is between 20 Ne (266 denier) and about 100 Ne (53.1 denier). In another example, the spun weft yarn count is between 20 Ne (266 denier) and about 60 Ne (88.6 denier). In another example, the spun weft yarn count is between 20 Ne (266 denier) and about 40 Ne (133 denier). In yet another example, the spun weft yarn count is 20 Ne (266 denier) and about 30 Ne (177 denier). The spun weft yarns may be single end yarns or plied yarns. For instance, the spun weft yarns may be plied yarns, such as two ply yarns or three-ply yarns.

In the woven fabric 210, the second weft yarn type within the weft yarn groups 240 a-240 d are continuous filament yarns 245 b-245 d. The continuous filament weft yarns 245 b-245 d may be formed from polyester filaments. However, other filament types are possible. Each continuous filament yarn 245 b-245 d may have a linear density between 15 denier and 150 denier.

In accordance with such an embodiment shown in FIGS. 7 and 8, the woven fabric 210 may include groups of a) one spun yarn and b) between one continuous filament yarn up to four continuous filament yarns (or more) with each continuous filament yarn having a denier between 15 denier and 150 denier. In one example, the woven fabric 210 may include groups of a) one spun yarn and b) two continuous filament yarns with each continuous filament yarn having a denier between 15 denier and 150 denier. In one example, the woven fabric 210 may include groups of a) one spun yarn and b) three continuous filament yarns with each continuous filament yarn having a denier between 15 denier and 150 denier. In one example, the woven fabric 210 may include groups of a) one spun yarn and b) four continuous filament yarns with each continuous filament yarn having a denier between 15 denier and 150 denier.

Another embodiment shown in FIGS. 9-10 is a sateen woven fabric 310 is formed from blended warp yarns 20 and a plurality of weft yarns arranged in weft yarn groups 340 a-340 d. FIGS. 9-10 are sectional views of the woven fabric 310. It should be appreciated that a plan view of the woven fabric 310 is similar to the view illustrated in FIG. 3. As shown in FIGS. 9-10, each weft yarn group 340 a-340 d includes multiple separate weft yarns 345 a, 345 b, 345 c, 345 d . . . 345 n that are substantially parallel with respect to each other and are grouped together as they extend along the weft insertion path 19 through the woven fabric 310. In the embodiment as shown in FIGS. 9 and 10, the blended spun yarns 345 a-345 d are a blend of cotton fibers and thermoplastic fibers or a blend of thermoplastic fibers and cellulosic synthetic fibers. The thermoplastic fibers are preferably polyester fibers. However, other thermoplastic fibers can be used.

The blended weft yarns 345 a-345 d may be any type of spun staple yarn structure. For example, the blended weft yarns may be ring spun yarns, open end yarns, rotor spun yarns, vortex spun yarns, core spun yarns, jet spun yarns, or compact spun yarns. Preferably, the blended spun weft yarns are ring spun yarns. The blended spun weft yarns 345 a-345 d can, however, be any type of spun yarn structure. The blended spun weft yarns 345 a-345 d may have a range of linear densities that are suitable for bedding applications. For example, the blended spun weft yarns can have a count between 20 Ne (266 denier) and about 120 Ne (44.3 denier). In one example, the blended spun weft yarn count is between 20 Ne (266 denier) and about 100 Ne (53.1 denier). In another example, the blended spun weft yarn count is between 20 Ne (266 denier) and about 60 Ne (88.6 denier). In another example, the blended spun weft yarn count is between 20 Ne (266 denier) and about 40 Ne (133 denier). In yet another example, the blended spun weft yarn count is 20 Ne (266 denier) and about 30 Ne (177 denier). The blended spun weft yarn may be single end yarns or plied yarns. For instance, the blended spun weft yarns may be plied yarns, such as two ply yarns or a three-ply yarns.

An alternative embodiment of the present disclosure is terry fabric 510 as shown in FIGS. 11 and 12. The terry woven fabric 510 includes a ground component 530 that includes warp yarns 520 and weft yarns 540 interwoven with the warp yarns 520. The terry woven fabric 510 also includes one or more pile components 550 a, 550 b. The ground component 530 includes a first side 532 and a second side 534 opposite the first side. The pile component 550 a and 550 b extend away from opposite sides 532 and 534 of the ground component 130 along a thickness direction 8. The warp yarns 120 extend along a warp direction 4, which is perpendicular to the weft direction 6 and the thickness direction 9. The weft yarns 540 extend along a weft or fill direction 6 that is perpendicular to the warp direction 4. The woven fabric 510 includes a face 12, and back 14 opposite the face 12 along a thickness direction 8 that is perpendicular to the warp direction 4 and the weft direction 6. The terminal ends of the pile components 550 a and 550 b can define the face 12 and back 14 of the woven fabric 510. The piles have a pile height H that extends from the ground component to the terminal ends of the piles.

As illustrated in FIG. 2A-2B, the terry woven fabric 510 includes a first pile component 550 a and a second pile component 550 b. However, the terry fabric may include only the one pile component. Each pile component 550 a, 550 b includes a plurality of piles 552 a, 552 b that project in a direction away from the ground component 530. The piles 552 a, 552 b are defined by pile yarns 554 a, 554 b interwoven with the ground component 530. The terry woven fabric 510 can be formed using any of the hygro yarn configurations described in the present disclosure. In one example, the pile yarns 554 a, 554 b may include the plied hygro yarns 80. Furthermore, one or both of the warp yarns 520 and the weft yarns 540 may include the plied hygro yarns 80. In another example, however, the pile yarns 554 a, 554 b may include the blended hygro yarn 80. In such an example, one or both of the warp yarns 520 and the weft yarns 540 may include the blended hygro yarn 80. The terry woven fabrics 510 may be converted bath and/or kitchen products, such as towel articles. Terry articles include a towel, a hand towel, a wash cloth, a bath robe, a rug, a kitchen towel, and the like.

The terry fabric 510 may include a plurality of yarns as described above. For instance, the warp yarns 530 are blended staple warp yarns each of which has cotton fibers and regenerated cellulosic fibers. The weft yarns and/or the pile yarns may include at least one yarn comprising thermoplastic fibers. In another example, the weft yarns and/or the pile yarns may include at least one yarn comprising a blend of cotton fibers and regenerated cellulosic fibers.

Turning to FIG. 13, a method of making woven fabric 10, 210, 310, 510 includes yarn formation 410 for the warp yarns 20 and weft yarns 40. Yarn formation 410 for the warp yarns can include staple yarn formation or spinning 412 and filament yarn formation 414 (where applicable). Staple yarn formation 412 may utilize any number of yarn formation systems and sub-systems. For instance, staple yarn formation may include bale opening, carding, optionally combing, drafting, roving, and yarn spinning (yarn spinning processes are not illustrated) to the desired count and twist level. In some cases, the warp yarns can be plied into 2-ply, 3-ply, or 4-ply configurations. After yarn spinning, the warp yarns are wound into the desired yarn packages for warping 420. In one example, ring spinning is the preferred spinning system. However, the warp yarns can be formed using open end spinning systems, rotor spun spinning systems, vortex spinning systems, core spinning yarns, jet spinning yarns, or compact spinning systems.

Following weft yarn spinning, a weft yarn may be prepared in winding 416 operation. Winding 416 may include use of a yarn winding apparatus (not shown) configured to wind separate yarns onto a multiple yarn packages.

Warping 420 follows the yarn formation 410 for woven and terry fabrics. Warping 420 is where warp yarn ends are removed from their respective yarn packages, arranged in a parallel form, and wound onto a warp beam. Warping 420 also includes a sizing step where a sizing agent is applied to each warp yarn to aid in fabric formation. Warping 420 results in a warp beam of warp yarns prepared for weaving. The warp beam can be positioned on a mounting arm of a weaving loom so that the warp yarns can be drawn through the loom components, as further described below. Terry fabric production may include pile warp beam as in known in the art.

Continuing with FIG. 13, after warping 420, weaving 440 operation forms a woven fabric with a weaving loom. More specifically, in weaving 440, the warp yarns are drawn-in (not shown) through various components of a weaving loom, such as drop wires, heddle eyes attached to a respective harness, reed and reed dents, in a designated order as is known in the art. After drawing-in is complete, fabric formation phase can begin.

During the formation phase of the weaving 440, the weft yarns 40, 140, 240, 240 are woven withthe warp yarns 20 to define the desired woven construction. The formation phase creates shed with the warp yarns 20 that the weft yarns can be inserted through across the width direction of the machine to create the desired woven fabric construction. For instance, shedding motions can include cam shedding, dobby shedding, or jacquard shedding motions, each of which can cause the selective raising and lowering of warp ends to create an open shed for weft insertion. The formation phase can utilize different weft insertion techniques, includes air-jet, rapier, or projectile type weft insertion techniques. In each weft insertion event, yarns are inserted through the shed. For instance, the weaving step can utilize a co-insertion so that multiple groups of weft yarn inserted through the shed during a single weft insertion event, as described above. The weaving step 440 can further include weaving one or more selvedge edges along a length L of the woven fabric. It should be appreciated that various woven constructions can made during weaving 440, including, but not limited to: plain weaves; basket weaves, satins; rib weaves; twill weaves, oxford weaves; percale weaves; and sateens.

After weaving 440, the woven fabric passes through desizing and bleaching 450. Desizing may be accomplished with enzymes as is known in the art. Bleaching may include typical bleaching agents, such as hydrogen peroxide.

After desizing and bleaching, coloring agents are applied to the woven fabric in dyeing operation 460. In accordance with the embodiment illustrated, the dyeing operation 460 applies color to any yarns, including any undyed continuous filament yarn and/or spun yarns, depending on the specific woven fabric construction. The dyeing operation is carried out in such way that coloring agents that are applied to the cotton fibers and or regenerated cellulosic fibers and/or the continuous filament yarns as the case may be. The dyeing operation may include sub operations depending on the fiber blends in the fabric. For instance, woven fabrics that include cotton fibers may involve application of reactive dyes. Woven fabrics that include continuous polyester filaments or staple length polyester fibers may include application of disperse dyes as is known persons of skill in the art.

Continuing with FIG. 13, after the dyeing operation 460, the woven fabric may be subjected to an optional finishing 470 operation. The optional fabric finishing 470 operation applies a composition including one or more of the functional agents to the woven fabric. The one or more functional agents may be, for example, a softener. Finishing includes a drying phase that is used to remove excess moisture from the woven fabric and the composition. After drying, the woven fabric may be optionally sanforized and calendared to adjust the hand and better control shrinkage.

After finishing 470, the fabrics may be assembled 480 into various textile articles. Article assembly 480 may include material handling a roll goods to present to cutting, hemming, and or folding machines that are used to prepare the articles. In one example, article assembly 480 includes cutting a panel of woven fabric to the appropriate length and width dimensions for the intended articles, such as the flat sheet or pillow case. The outer edges of the panel may be hemmed or surged to create finished edge. Secondary components can be attached to the panel at this stage. For example, ribbing, block hems, or binding can be sewn or otherwise attached to the panel. For fitted sheets, elastic materials are secured the at least the corner regions along the edge of the panel. For comforters, the fabrics can be cut to size and combined with desired batting or fill (e.g. fiber, feather, etc.). Accordingly, article assembly 480 includes forming one or more bedding articles of a bedding system. The bedding articles include at least one of a flat sheet, a fitted sheet, a pillow case, a sham, a comforter, a duvet, a bed-skirt, coverlet and a blanket.

After the assembling step, a packaging step 490 places the bedding article in suitable packaging for shipment. The packaging 490 may include automatically folding the formed articles, which are in panel form, into a folded configuration. The folded article is then placed in an outer package for shipment.

While the disclosure is described herein using a limited number of embodiments, these specific embodiments are not intended to limit the scope of the disclosure as otherwise described and claimed herein. The precise arrangement of various elements and order of the steps of articles and methods described herein are not to be considered limiting. For instance, although the steps of the methods are described with reference to sequential series of reference signs and progression of the blocks in the figures, the method can be implemented in a particular order as desired. 

What is claimed:
 1. A performance fabric, comprising: a plurality of warp yarns extending along a warp direction, the warp yarn including a first warp yarn and a second warp yarn that is directly adjacent to the first warp yarn, wherein the plurality of warp yarns are blended staple warp yarns each of which has cotton fibers and regenerated cellulosic fibers; a plurality of weft yarns interwoven with the plurality of warp yarns to define a woven fabric structure, wherein the plurality of weft yarns including at least one yarn comprising thermoplastic fibers.
 2. The performance fabric of claim 1, wherein the fabric structure has a thread count from about 200 to about
 1400. 3. The performance fabric of claim 1, wherein the plurality of weft yarns are arranged in weft yarn groups, wherein adjacent weft yarn groups each have a fill insertion path that extends over the first warp yarn and under the second warp yarn that is directly adjacent to the first warp yarn, each weft yarn group including the at least one yarn comprising thermoplastic fibers.
 4. The performance fabric of claim 1, wherein the blended staple warp yarn has between 20% to about 80% by weight of the cotton fibers.
 5. The performance fabric of claim 4, wherein the blended staple warp yarn has between 20% to about 80% by weight of the regenerated cellulosic fibers.
 6. The performance fabric of claim 4, wherein the blended staple warp yarn has between 25% to about 45% by weight of the cotton fibers, and between 55% to about 75% by weight of the regenerated cellulosic fibers.
 7. The performance woven sheeting fabric of any one of claims 1 to 6, wherein the blended staple warp yarn has a count from 30 Ne to about 120 Ne.
 8. The performance fabric of claim 1, wherein the thermoplastic fibers are continuous filaments, and the at least one yarn of the weft yarns is at least one continuous filament yarn.
 9. The performance fabric of claim 8, wherein the at least one continuous filament is a polyester filament yarn.
 10. The performance fabric of claim 1, wherein the thermoplastic fibers are continuous filaments, and the at least one yarn of the weft yarns is at least one continuous filament yarn and at least one spun staple yarn.
 11. The performance fabric of claim 10, wherein the at least one spun staple yarn is a spun staple yarn of cotton fibers.
 12. The performance fabric of claim 10, wherein the at least one spun staple yarn is a blended staple yarn of cotton fibers and regenerated cellulosic fibers.
 13. The performance fabric of claim 10, wherein the at least one spun staple yarn is a blended staple yarn of cotton fibers and polyester staple fibers.
 14. The performance fabric of claim 1, wherein the thermoplastic fibers are thermoplastic staple fibers, and wherein the at least one yarn in the weft yarns is at least one blended staple yarn that includes a) the thermoplastic staple fibers and b) either cotton fibers or regenerated cellulosic fibers.
 15. The performance fabric of claim 14, wherein the thermoplastic staple fibers in the weft yarns are polyester staple fibers.
 16. The performance fabric of claim 14, wherein the at least one blended staple yarn includes polyester staple fibers and cotton fibers.
 17. The performance fabric of claim 14, wherein the at least one blended staple yarn includes polyester staple fibers and regenerated cellulosic fibers.
 18. A performance fabric, comprising: a plurality of warp yarns extending along a warp direction, the warp yarn including a first warp yarn and a second warp yarn that is directly adjacent to the first warp yarn, wherein the plurality of warp yarns are blended staple warp yarns each of which has cotton fibers and regenerated cellulosic fibers; a plurality of weft yarns interwoven with the plurality of warp yarns to define a woven fabric structure, wherein the plurality of weft yarns including at least one yarn comprising a blend of cotton fibers and regenerated cellulosic fibers.
 19. The performance fabric of claim 18, wherein the fabric structure has a thread count from about 200 to about
 1400. 20. The performance fabric of claim 18, wherein the plurality of weft yarns are arranged in weft yarn groups, wherein adjacent weft yarn groups each have a fill insertion path that extends over the first warp yarn and under the second warp yarn that is directly adjacent to the first warp yarn, each weft yarn group including the at least one yarn comprising a blend of cotton fibers and regenerated cellulosic fibers.
 21. The performance fabric of claim 18, wherein the blended staple warp yarn has between 20% to about 80% by weight of the cotton fibers.
 22. The performance fabric of claim 21, wherein the blended staple warp yarn has between 20% to about 80% by weight of the regenerated cellulosic fibers.
 23. The performance fabric of claim 21, wherein the blended staple warp yarn has between 25% to about 45% by weight of the cotton fibers, and between 55% to about 75% by weight of the regenerated cellulosic fibers.
 24. The performance woven sheeting fabric of any one of claims 18 to 23, wherein the blended staple warp yarn has a count from 30 Ne to about 120 Ne.
 25. A performance fabric, comprising: a plurality of warp yarns extending along a warp direction, the warp yarn including a first warp yarn and a second warp yarn that is directly adjacent to the first warp yarn, wherein the plurality of warp yarns are blended staple warp yarns each of which has cotton fibers and regenerated cellulosic fibers; a plurality of weft yarns interwoven with the plurality of warp yarns to define a woven fabric structure, wherein the plurality of weft yarns are arranged in weft yarn groups, wherein adjacent weft yarn groups each have a fill insertion path that extends over the first warp yarn and under the second warp yarn that is directly adjacent to the first warp yarn, each weft yarn group including at least one yarn comprising a blend of cotton fibers and regenerated cellulosic fibers.
 26. A performance fabric, comprising: a plurality of warp yarns extending along a warp direction, the warp yarn including a first warp yarn and a second warp yarn that is directly adjacent to the first warp yarn, wherein the plurality of warp yarns are blended staple warp yarns each of which has cotton staple fibers and regenerated cellulosic fibers; a plurality of weft yarns interwoven with the plurality of warp yarns to define a woven fabric structure having a thread count from about 200 to about 1400; and wherein the plurality of weft yarns are arranged in weft yarn groups, wherein adjacent weft yarn groups each have a fill insertion path that extends over the first warp yarn and under the second warp yarn that is directly adjacent to the first warp yarn, each weft yarn group including at least continuous filament polyester yarn.
 27. A performance fabric, comprising: a plurality of warp yarns extending along a warp direction, the warp yarn including a first warp yarn and a second warp yarn that is directly adjacent to the first warp yarn, wherein the plurality of warp yarns are blended staple warp yarns each of which has cotton staple fibers and regenerated cellulosic fibers; a plurality of weft yarns interwoven with the plurality of warp yarns to define a woven fabric structure having a thread count from about 200 to about 1400; and wherein the plurality of weft yarns are arranged in weft yarn groups, wherein adjacent weft yarn groups each have a fill insertion path that extends over the first warp yarn and under the second warp yarn that is directly adjacent to the first warp yarn, each weft yarn group including a) at least one spun staple yarn and b) at least one continuous filament polyester yarn.
 28. A performance fabric, comprising: a plurality of warp yarns extending along a warp direction, the warp yarn including a first warp yarn and a second warp yarn that is directly adjacent to the first warp yarn, wherein the plurality of warp yarns are blended staple warp yarns each of which has cotton staple fibers and regenerated cellulosic fibers; a plurality of weft yarns interwoven with the plurality of warp yarns to define a woven fabric structure having a thread count from about 200 to about 1400; and wherein the plurality of weft yarns are arranged in weft yarn groups, wherein adjacent weft yarn groups each have a fill insertion path that extends over the first warp yarn and under the second warp yarn that is directly adjacent to the first warp yarn, each weft yarn group including at least one spun staple yarns comprising either a) a blend of thermoplastic fibers and cotton fibers, or b) a blend of thermoplastic fibers and regenerated cellulosic fibers. 